By: Oladayo Ogunnoiki, Statistics Canada

Introduction

In May 2016, Microsoft introduced Tay to the Twittersphere. Tay was an experimental artificial intelligence (AI) chatbot in "conversational understanding". The more you chatted with Tay, the smarter it would become. However, it didn't take long for the experiment to go awry. Tay was supposed to be engaging people in playful conversation, but this playful banter quickly turned into misogynistic and racist commentary.

Of course, the public was perplexed by this turn of events. If this bot was inherently rude, why wouldn't other AI models also go off course? Most Twitter users felt that this bleak event was only a glimmer of what was to come if our future was indeed rich in AI models. However, most data scientists understood the real reason for Tay's negative commentary – the bot was simply repeating what it had learned from the users themselves (Vincent, 2016).

The world of AI continues to grow exponentially and with stories like this happening all the time, there's a strong need to increase the public's trust in AI products. To gain their trust, transparency and explain-ability is of the utmost importance.

One of the primary questions for anyone interacting with an AI model like Tay, is: "why did the model make that decision?" Multiple tools have been designed to explain the rationale behind these models and answer that question. It may be to no one's surprise that visual explanations are an efficient way of explaining this. In their work, Ramprasaath, et al. (2017) outline the requirements of a good visual explanation– they must be class discriminative and should have a high-resolution. These criteria serve as guidelines for identifying the challenge to be addressed: creating a solution that provides a high resolution and class discriminative visual explanation for decisions of a neural network.

Some of the techniques that provide visual explanations include deconvolution, guided backpropagation, class activation mapping (CAM), Gradient-weighted CAM (Grad-CAM), Grad-CAM++, Hi-Res-CAM, Score-CAM, Ablation-CAM, X-Grad-CAM, Eigen-CAM, Full-Grad, and deep feature factorization. For this article, we'll focus on Grad-CAM.

Grad-CAM is an open-source tool that produces visual explanations for decisions from a large class of convolutional neural networks. It works by highlighting the regions of the image that have the highest influence on the final prediction of the deep neural network, thereby providing insight into the decision-making process of the model.

Grad-CAM is based on CAM which uses the activation of the feature maps with respect to the target class. It's specific to certain types of neural networks, such as the Visual Geometry Group network and residual network (ResNet). It uses the gradient of the target class with respect to the feature maps in the final layer. Grad-CAM is a generic method that can be applied to different types of neural networks. Combining features makes Grad-CAM a reliable and accurate tool for understanding the decision-making process of deep neural networks. Guided Grad-CAM is enhanced by incorporating the gradients of the guided backpropagation process to produce a more refined heatmap. One limitation is that it's only able to visualize the regions of the image that are most important for the final prediction, rather than the entire decision-making process of the deep neural network. This means that it may not provide a complete understanding of how the model is making its predictions.

The advantages of Grad-CAM include:

• No trade off of model complexity and performance for more model transparency.
• It's applicable to a broad range of convolutional neural networks (CNNs).
• It's highly class discriminative.
• Useful for diagnosing failure modes by uncovering biases in datasets.
• Helps untrained users to recognize a stronger network than a weaker one, even when the predictions are identical.

Methodology

Grad-CAM can be used in multiple computer vision projects such as image classification, semantic segmentation, object detection, image captioning, visual question answering, etc. It can be applied on CNNs and has recently been made available on transformer architectures.

Highlighted below is how Grad-CAM works in image classification, where the objective is to discriminate between different classes:

In the case of an image classification task, to obtain the Grad-CAM class-discriminative localization map,LGrad-CAMc
,  for a model on a specific class, the steps below are followed:

• For a specific class, c, the partial derivative of the score, $y^c$ , of the class, c, in respect to feature maps, $A^k$ , of a convolutional layer is calculated using backpropagation.
  ∂yc∂Aijk
• The gradients flowing back due to backpropagation are pooled via global average pooling. This produces a set of scalars of weights. These are the neuron importance weights.
  αkc= 1Z∑i∑j∂yc∂Aijk
• The derived scalar weights are applied (linear combination) to the feature map. The result is passed through a Rectified Linear Unit (ReLU) activation function.
  LGrad-CAMc=ReLU∑kαkcAk
• The result is scaled and applied to the image, highlighting the focus of the neural network. As seen, a ReLU activation function is applied to the linear combination of maps, because it's only interested in the pixels or features that have a positive influence on the class score, $y^c$ .

Demonstration of Grad-CAM

Figure 2 is an image of two Egyptian cats and two remote controls. The image was derived from the Hugging Face's cat image dataset, using their Python library. The objective is to identify the items within the image using different pretrained deep learning models. A PyTorch package called the PyTorch-GradCAM is used. The Grad-CAM feature identifies aspects of the image that activate the feature map of the Egyptian cat class and the remote-control class. After following the PyTorch-GradCAM tutorial, the Grad-CAM results are replicated for different deep neural networks.

Figure 2 is parsed through a pretrained residual neural network (Resnet-50) as per the PyTorch-Grad-CAM tutorial. Figure 3 is the image generated using Grad-CAM. For the Egyptian cat class, the leg, stripes, and faces of the cats activated the feature map. For the remote controls, the buttons and profile are what activated the feature map. The top 5k predicted classes in order of logit, are remote control, tiger cat, Egyptian cat, tabby cat, and pillow. This model seems to be more confident the image contains remote controls and cats. Though less confident, the pillow category made the top five of the listed categories. This could be because the model was trained with cat-printed pillows.

Like the Resnet-50 architecture, the same image is parsed through a pretrained shifted window transformer. Figure 4 shows the cats' fur, stripes, faces, and legs as activated regions in the feature map in respect to the Egyptian cat category. The same occurs in relation to the feature map in respect to the remote controls. The top 5k predicted classes, in order of logit, are tabby cat, tiger cat, domestic cat, and Egyptian cat. This model is more confident that cats are in this image than remote controls.

As seen above, more regions of the feature map are activated, including sections of the image that didn't include cat features. The same occurs for regions of the feature map in respect to the remote-control class. The top 5k predicted classes, in order of logit, are Egyptian cat, tiger cat, tabby cat, remote control, and lynx.

The Grad-CAM results with the top 5k categories for different architectures can be used to favour a selection of the vision transformer (VIT) architecture for tasks related to identifying Egyptian cats and remote controls.

Conclusion

Some of the challenges in the field of AI includes increasing the trust of people in the developed models and understanding the rationale behind the decision making of these models during development. Visualizations tools like Grad-CAM provide insight into these rationales and aid in highlighting different failure modes of AI models for specific tasks. It can be used to identify errors in the models and improve their performance. On top of Grad-CAM, there are other visualization tools that have been developed such as Score-CAM, which performs even better in interpreting the decision-making process of deep neural networks. Though Grad-CAM will be selected over Score-CAM due it's simplicity and agnosticism to model architectures. The use of tools such as Grad-CAM, should be encouraged in visually explaining the reason behind the decisions of AI models.

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References

• S. R. Ramprasaath, C. Michael, D. Abhishek, V. Ramakrishna, P. Devi and B. Dhruv, "Grad-CAM: Visual Explanations from Deep Networks via Gradient-based Localization," in ICCV, IEEE Computer Society, 2017, pp. 618-626.
• Z. Bolei, K. Aditya, L. Agata, O. Aude and T. Antonio, "Learning Deep Features for Discriminative Localization," CoRR, 2015.
• J. Vincent, "Twitter taught Microsoft's AI chatbot to be racist in less than a day", in The Verge, 2016.

Zero knowledge proof – Proving something without exchanging evidence

By: Betty Ann Bryanton, Canada Revenue Agency

Introduction

Enormous amounts of data are collected by government agencies, search engines, social networking systems, hospitals, financial institutions, and other organizations. This data, centrally stored, is at risk of security breaches. Additionally, individuals browse the internet, accept cookies, and share personally identifiable information (PII) in exchange for services, benefits, recommendations, etc. To facilitate e-commerce and access services, individuals need to authenticate, which means providing 'evidence' to prove they are who they say they are. This may mean providing a password, a driver's license, a passport number, or another personal identifier. These could potentially be stolen, and sharing this data may compromise related PII, such as age and home address. Zero knowledge proofs can assist in these scenarios.

What is Zero Knowledge Proof?

A Zero-Knowledge Proof (ZKP) is one of the cryptographic privacy-enhancing computational (PEC) techniques and may be used to implement granular, least access privacy controls and privacy-by-design^Footnote1 principles.

Typically, a proof that some assertion X is true also reveals some information about why X is true. ZKPs, however, prove that a statement is true without revealing any additional knowledge. It's important to note that ZKPs do not guarantee 100% proof, but they do provide a very high degree of probability.

ZKPs use algorithms that take data as input and return either 'true' or 'false' as output. This allows two parties to verify the truth of information without exposing the information or how the truth was determined. For example, an individual can prove the statement "I am an adult at least 21 years old" without providing data for verification to a central server.

ZKP was introduced by researchers at MIT in 1985^Footnote2 and is now being used in many real-world applications.

ZKP vs other concepts

ZKP is distinct from the following concepts:

• Zero trust (Zero Trust vs. Zero Knowledge - REDCOM or Zero trust vs. zero-knowledge proof: What's the difference? | TechTarget)
• Zero knowledge encryption (What Is Zero-Knowledge Encryption and Why Should You Use It?)
• Zero trust architecture (Zero Trust Architecture)
• Zero trust access and zero trust network access (ZTNA) (Zero Trust, ZTA, and ZTNA: Differences Explained | CISO Collective)

Further, ZKP should not be confused with Advanced Encryption Standard (AES), where the parties share a secret number. In ZKP, the prover demonstrates their possession of a secret number without divulging that number. In both scenarios the parties arrive at a shared secret, but with ZKP, the goal is to make claims without revealing extraneous information.

How does ZKP work?

To understand how ZKP works, consider the scenario of a prover (Peggy) and a verifier (Victor). The goal of the ZKP is to prove a statement with very high probability without revealing any additional information.

Peggy (the prover) wants to prove to Victor (the verifier, who is colour-blind and does not trust her) that two balls are of different colours (e.g., green and red). Peggy asks Victor to reveal one of the balls, then put the two balls behind his back. Then Peggy asks Victor to switch them or not, then reveal one to her. She answers if it's the same colour or different than the previous one. Of course, she could be guessing or lying, or even colour-blind, herself. Thus, in order to convince him she's telling the truth, this process must be repeated many, many times. By doing so, eventually Peggy can convince Victor of her ability to correctly identify the different colours.

This scenario satisfies the three criteria of a ZKP:

1. Soundness (the quality of being based on valid reason): If Peggy was not telling the truth, or was colour-blind, she could only guess correctly 50% of the time.
2. Completeness: After repeating this process ('the proof') many, many times, the probability of Peggy correctly guessing would be very low, convincing Victor that the balls are of different colours.
3. Zero-knowledge: Victor does not learn anything additional; he never even learns which ball is green and which is red.

What is explained above is interactive proving, requiring a back-and-forth communication between two parties. Today's ZKPs employ non-interactive proving, where two parties have a shared key to transmit and receive information. For example, a government-issued key as part of a passport could be used to demonstrate citizenship without revealing the passport number or the citizen's name.

Why is it important?

ZKPs assure a secure and invisible flow of data, protecting user information from potential leaks and identity theft. This enhances e-commerce, by allowing more private and secure transactions.

The use of ZKPs not only helps combat data security risk, but this minimum viable verification technique helps prevent the disclosure of more PII than necessary. This benefits both individuals and organizations. Individuals do not have to share their PII and organizations that are facing an increase in security breaches, and thus, dealing with significant costs, harm to reputations, and loss of trust, don't receive the PII to be breached.

Another benefit for both individuals and organizations is more efficient verification, reducing bottle-necked processes that rely on manual or inefficient burden of proof.

Having positive and efficient verification between parties (even untrusted ones) opens up a variety of avenues for collaboration and enquiry.

Applications and Use Cases

ZKPs can protect data privacy in a diverse set of applications and use cases, including:

• Finance: A mortgage or leasing applicant can prove their income falls within a certain range without revealing their salary. (Financial institution ING is already using this technology, according to Dilmegani, 2022.)
• Online voting: ZKP can enable anonymous and verifiable voting and help prevent voting fraud or manipulation.
• Machine Learning: A machine learning algorithm owner can convince others about the model's results without revealing any information about the model.
• Blockchain Security: Transactions can be verified without sharing information such as wallet addresses and amounts with third party systems.
• Identity and credential management: Identity-free verification could apply to authentication, end-to-end encrypted messaging, digital signatures, or any application requiring passwords, passports, birth certificates, driving licences, or other forms of identity verification. Fraud prevention systems could validate user credentials and PII could be anonymized to comply with regulations or for decentralized identity.
• International security: ZKPs enable the verification of the origin of a piece of information without revealing its source. This means cyber-attacks can be attributed to a specific entity or nation without revealing how the information was obtained. This is already being used by the United States' Department of Defense  (Zero-knowledge proof: how it works and why it's important, n.d.).
• Nuclear disarmament: Countries could securely exchange proof of disarmament without requiring physical inspection of classified nuclear facilities.
• COVID-19 vaccine passports and travel: As currently done in Denmark, individuals could prove their vaccination status without revealing their PII (Shilo, 2022).
• Auditing or compliance applications: Any process that requires verification of compliance could use ZKP. This could include verifying that taxes are filed, an airplane was maintained, or data is retained by a record keeper.
• Anonymous payments: Credit card payments could be made without being visible to multiple parties such as payments providers, banks, and government authorities.

Challenges

While there are many benefits, there are also challenges that need to be taken into consideration if an organization wants to use ZKPs.

• Computation intensity: ZKP algorithms are computationally intense. For interactive ZKPs, many interactions between the verifier and the prover are required, and for non-interactive ZKPs, significant computational capabilities are required. This makes ZKPs unsuitable for slow or mobile devices and may cause scalability issues for large enterprises.
• Hardware costs: Applications that want to use ZKPs must factor in hardware costs which may increase costs for end-users.
• Trust assumptions: While, some ZKP public parameters are available for reuse, and participants in the trusted setup are assumed to be honest, recipients must rely on the honesty of the developers (What are zero-knowledge proofs?, 2023).
• Quantum computing threats: While ZKP cryptographic algorithms are currently secure, the development of quantum computers could eventually break the security model.
• Costs of using the technology: The costs of ZKPs can vary based on setup requirements, efficiency, interactive requirements, proof succinctness and the hardness assumptions required (Big Data UN Global Working Group, 2019).
• Lack of standards: Despite ongoing initiatives to standardize zero knowledge techniques and constructions, there is still an absence of standards, systems, and homogeneous languages.^Footnote3
• No 100% guarantee: Though the probability of verification while the prover is lying can be significantly low^Footnote4, ZKPs do not guarantee the claim is 100% valid. 
• Skills: ZKP developers should have expertise in ZKP cryptography and be aware of the subtleties and differences between the guarantees provided by ZKP algorithms.

What's next?

In recent years there has been a strong push for adopting zero knowledge in software applications. Several organizations have built applications using ZK capabilities, and ZKPs are widely used to safeguard blockchains. For example, the city of Zug in Switzerland has registered all its citizen IDs on a blockchain (Anwar, 2018).

Though there needs to be improvements in ZK education, standardization, and privacy certifications to improve trust in ZK products and services, ZKPs have great potential in saving organizational costs due to security breaches, as well as preserving users' privacy, and reducing PII as a product for sale. ZKPs help an organization move from reacting to security breaches to preventing them.

Meet the Data Scientist

If you have any questions about my article or would like to discuss this further, I invite you to Meet the Data Scientist, an event where authors meet the readers, present their topic and discuss their findings.

Thursday, June 15
1:00 to 4:00 p.m. ET
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Related Topics

Authentication, Blockchain, Web 3.0, Privacy-Enhancing Computation (PEC) techniques: Differential Privacy, Homomorphic Encryption, Secure Multiparty Computation, Trusted Execution Environment

References

• Alameda, T. (2020, June 23). Zero Knowledge Proof: how to maintain privacy in a data-based world. Retrieved from BBVA: https://www.bbva.com/en/zero-knowledge-proof-how-to-maintain-privacy-in-a-data-based-world/
• Anwar, H. (2018, August 7). Web 3.0 Blockchain Technology Stack: The Comprehensive Guide. Retrieved from 101 Blockchains: https://101blockchains.com/web-3-0-blockchain-technology-stack/
• Barak, B. (2016, Spring). Lecture 14: Zero knowledge proofs [PDF]. Retrieved from Boaz Barak: https://www.boazbarak.org/cs127spring16/chap14_zero_knowledge.pdf
• Big Data UN Global Working Group. (2019, April 1). UN Handbook on Privacy-Preserving Computation Techniques [PDF]. Retrieved from United Nations Statistics Division: https://unstats.un.org/bigdata/task-teams/privacy/UN%20Handbook%20for%20Privacy-Preserving%20Techniques.pdf
• Dilmegani, C. (2022, December 21). Zero-Knowledge Proofs: How it Works & Use Cases in 2023. Retrieved from AI Multiple: https://research.aimultiple.com/zero-knowledge-proofs/
• Farahmand, H. (2021, September 6). Guidance for Blockchain Solution Adoption (ID: G00463865). Retrieved from Gartner: https://www.gartner.com
• Fenzi, G. (2019, September). Zero Knowledge Proofs Theory and Applications [PDF]. Retrieved from University of St. Andrews School of Computer Science: https://info.cs.st-andrews.ac.uk/student-handbook/files/project-library/cs4796/gf45-Final_Report.pdf
• Gehrke, J., Lui, E., & Pass, R. (2011, May 20). Towards Privacy for Social Networks: A Zero-Knowledge Based Definition of Privacy [PDF]. Retrieved from Cornell University: http://www.cs.cornell.edu/~luied/zkPrivacyFinal.pdf
• Howell, J. (2022, June 22). Zero Knowledge Proof And Its Importance To Web3. Retrieved from 101 Blockchains: https://101blockchains.com/zero-knowledge-proof-for-web3/
• itsupportla. (2021, August 31). Online Transactions and Zero-Knowledge Proofs. Retrieved from IT Support LA: https://itsupportla.com/online-transactions-and-zero-knowledge-proofs/
• Sahai, A. (2022, January 18). Computer Scientist Explains One Concept in 5 Levels of Difficulty | WIRED. Retrieved from YouTube: https://www.youtube.com/watch?v=fOGdb1CTu5c
• Shilo, V. (2022, February 3). Zero-Knowledge Proof: Protecting Your Personal Information Without Sacrificing Open Data. Retrieved from Forbes: https://www.forbes.com/sites/forbestechcouncil/2022/02/03/zero-knowledge-proofprotecting-your-personal-information-without-sacrificing-open-data/?sh=49e1701a6eb5
• Takyar, A. (n.d.). What is Zero Knowledge Proof and Its Role in Blockchain? Retrieved from LeewayHertz: https://www.leewayhertz.com/zero-knowledge-proof-and-blockchain/
• Tyson, M. (2022, August 4). Zero-knowledge proof finds new life in the blockchain. Retrieved from InfoWorld: https://www.infoworld.com/article/3668549/zero-knowledge-proof-finds-new-life-in-the-blockchain.html
• What are zero-knowledge proofs? (2023, April 19). Retrieved from Ethereum: https://ethereum.org/en/zero-knowledge-proofs/
• Zero-knowledge proof. (n.d.). Retrieved from Wikipedia: https://en.wikipedia.org/wiki/Zero-knowledge_proof
• Zero-knowledge proof: how it works and why it's important. (n.d.). Retrieved from Mangrovia Blockchain Solutions: https://www.mangrovia.solutions/en/zero-knowledge-proof-how-it-works-and-why-its-important/